BIO 121 LAB INSTRUCTIONS Lab 6- Photosynthesis All Organisms Need Energy to Function. Heterotrophic Organisms Obtain Their Energ

BIO 121 LAB INSTRUCTIONS Lab 6- Photosynthesis All Organisms Need Energy to Function. Heterotrophic Organisms Obtain Their Energ

BIO 121 LAB INSTRUCTIONS Lab 6- Photosynthesis All organisms need energy to function. Heterotrophic organisms obtain their energy by oxidizing reduced organic compounds and recovering the energy stored in the C-H bonds. However, those C-H bonds were originally created using energy from sunlight, by a process called photosynthesis. Photosynthesis is therefore the most important biochemical process on earth: virtually all living organisms depend directly or indirectly on photosynthesis for energy, and all aerobic organisms also depend on photosynthesis for oxygen. The overall reaction for photosynthesis is quite simple: 2 2 6 12 6 2 2 6 CO + 12 H O + light energy <=> C H O + 6 O + 6 H O however, the reactions by which this is accomplished are diabolically complex. Photosynthesis can be separated into two sets of reactions: the light reactions, which capture light and use its energy to make ATP and NADPH, and the light-independent reactions, which use the ATP and NADPH formed by the light reactions to convert CO2 into carbohydrates. Both sets of reactions occur in the chloroplasts of higher plants; however, the light reactions occur in the thylakoids, while the light-independent reactions occur in the stroma. Photosynthesis is described in greater detail in chapter 8 of your text. Instructions for BIO 121 Lab 6: photosynthesis Page 2 II. The light reactions These can be subdivided into four stages: capturing light, electron transport, water-splitting, and chemiosmotic ATP synthesis. Light is captured by pigments which absorb photons of specific wavelengths. When this occurs, the energy of the photon is added to the energy of an electron within the pigment, which moves to an orbital more distant from the nucleus. Photosynthetic pigments are usually found in a precise array called a photosystem, which is constructed such that energy absorbed by any pigment within the photosystem is transferred by inductive resonance to a special pigment at the center of the array called the reaction center chlorophyll. When light energy is transferred to the reaction center chlorophyll an electron within the reaction center becomes "excited" and is transferred to a primary electron acceptor. The primary electron acceptor then passes the excited electron down an electron transport chain located on the thylakoid membrane. As the electrons move from one carrier to another, energy is released and some is used to pump H+ into the thylakoid lumen. Plants have two photosystems, Photosystem I and Photosystem II. In Photosystem I the reaction center chlorophyll is called P700, while the reaction center chlorophyll in Photosystem II is called P680. Photosystem I participates in two reactions: cyclic photophosphorylation and noncyclic photophosphorylation. In cyclic photophosphorylation electrons transferred from P700 to the electron transport system are returned to P700. In noncyclic photophosphorylation electrons transferred from P700 are passed via a series of intermediates to NADP+ to form NADPH. The electrons lost from P700 are replaced by electrons transferred from P680. When Photosystem II absorbs a photon P680 donates the excited electron to an electron transport system which ultimately donates the electron to P700, after using some of the energy released to pump H+ into the thylakoid lumen. The electrons lost from P680 are replaced by electrons removed from water by the water- splitting enzyme located in the thylakoid lumen. In the process water is oxidized to oxygen and H+, further increasing the [H+] in the thylakoid lumen. In the final stage of the light reactions, the difference in [H+] between the lumen and the stroma is used to synthesize ATP by chemiosmosis as H+ in the thylakoid lumen diffuses through ATP synthetase into the stroma. III. The light-independent reactions. The light-independent reactions use the NADPH and ATP generated by the light reactions to incorporate CO2 into organic molecules and reduce these to form carbohydrates. This is done by means of a series of reactions called the Calvin or PCR (photosynthetic carbon reduction) cycle. The Calvin cycle can be split into 3 phases: CO2 fixation, reversing glycolysis, and regenerating ribulose 1,5-bisphosphate (RuBP). CO2 is fixed (attached to a molecule that prevents it from escaping) by an enzyme called ribulose 1,5-bisphosphate carboxylase/oxygenase, or Rubisco, for short. Rubisco adds CO2 to RuBP to form a 6 carbon molecule which is rapidly converted to two molecules of 3-phosphoglycerate (which are also intermediates in glycolysis). 3-phosphoglycerate is next converted to 3-phosphoglyceraldehyde, which is either used for carbohydrate synthesis, or to regenerate RuBP via a fiendishly complex set of reactions. IV. This week's activities You will examine five aspects of photosynthesis: photosynthetic pigments, the absorption spectrum of chlorophyll, electron transport, oxygen evolution and CO2 uptake. Instructions for BIO 121 Lab 6: photosynthesis Page 3 A. Fractionation of photosynthetic pigments The first event in photosynthesis - the primary photoevent- is always the absorption of a photon by a pigment. The most abundant pigments are chlorophylls a and b. However, as you will see in part B, chlorophylls can only absorb a portion of the visible spectrum. Plants use accessory pigments to capture light which is not absorbed by chlorophylls, primarily carotenoids and xanthophylls. In this exercise you will examine the pigments extracted from several different plant tissues. Obtain a TLC plate from the side table. HANDLE THE PLATE ONLY BY THE CORNERS. Lay the plate on a clean piece of paper towel. Lay a ruler across the plate 1.5 cm from the bottom, and mark four dots 1, 2, 3 and 4 cm from the left edge. Write your initials at the top of the plate, and gently draw a line across the silica gel 1 cm below the top. You have 4 extracts of plant pigments labeled "green leaf,” "yellow leaf,” “carrot,” and "beets.” Use a micropipet to spot 2 µl of green leaf extract onto the dot 1 cm from the edge. Then, spot 2 µl of yellow leaf extract at 2 cm, 2 µl of carrot extract at 3 cm spot and 2 µl of beet extract at 4 cm. Once your plate is dry, give it to your instructor or TA who will place it in one of the tanks containing solvent. They will let the plate develop until the solvent front reaches the line you drew 1 cm from the top. When your plate is ready, they will remove it from the tank and trace the solvent front using a pencil if it was not at the line you drew. Then allow the solvent to evaporate by placing it in the fume hood. Be sure to handle your plate only by its edges. When the solvent is completely evaporated note the color and position of each visible pigment. Measure the distance between the front of each spot and the origin (where you placed the pigment). Then measure the distance from the origin to the solvent front. Do this for each extract. Then, for each, calculate the Rf , the distance that the pigment moved divided by the distance that the solvent moved (Rf will be a number between 0 and 1). Number your pigments from the bottom, i.e, #1 is closest to the origin. Chlorophyll a is blue-green, chlorophyll b is yellow-green, carotenoids are yellow-orange, and xanthophylls are yellow. The order of Rfs should be carotenoids > xanthophylls > chlorophyll a > chlorophyll b. Report your findings on your datasheet. Your introduction should explain what photosynthetic pigments are, why plants have more than one kind of photosynthetic pigment, and what the purpose of the experiment is. Your results should include sentences saying what you set out to do, where the results are presented, and what your key results were. It should also include a table of Rf values and colors for each of the pigments detected in the 4 extracts. Your discussion should include a tentative identification of the main pigments in each extract, your reasoning, and some discussion of the differences between the green and yellow leaves. B. Absorption spectrum of photosynthetic pigments. Recall that the first event in photosynthesis is always the absorption of a photon by a pigment. Therefore, only light which is absorbed by a photosynthetic pigment can be used for photosynthesis. The second experiment determines which wavelengths of light are absorbed by pigments in leaves. Instructions for BIO 121 Lab 6: photosynthesis Page 4 1. Turn on the Spec 20 and allow it to warm up. 2. Set the Spec 20 to 400 nm, then adjust it to 0% transmittance using the left knob with nothing in the chamber. 3. Insert a blank tube containing 80% acetone and adjust the Spec 20 to 0 absorbance using the right knob. 4. Put 5 mls of leaf extract in 80% acetone into a Spec 20 tube, and measure its absorbance. Record the data in Table II of your data sheet. 5. Change the wavelength to 405 nm, and repeat steps 2-4. 6. Repeat, increasing by 5 nm each time until you reach 500 nm. 7. From 500 to 620 nm record the absorbance at 10 nm intervals (as indicated on your datasheet). 8. From 620 to 700 nm record the absorbance at 5 nm intervals, then stop recording once you reach 700 nm. 9. Plot absorbance vs wavelength on figure 1, page 3. Report your findings on your datasheet in the usual format. In your introduction you should explain (one sentence) what photosynthetic pigments are, why you are interested in determining the absorption spectrum of a leaf, and what you specifically set out to do in this experiment. Your results should explain briefly why you performed the experiment, where the results are, and what the key results were.

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